RU2022474C1 - Transmitter of stereophonic broadcasting in system of multichannel telephony - Google Patents

Abstract

FIELD: communication equipment. SUBSTANCE: for decrease of induced distortions by diminished number of stages of conversion in channels A and B first conversion is introduced directly on virtual carrier frequency of channel A (82 kHz). Second conversion on frequency 168 kHz is introduced additionally for channel B as a result of which virtual carrier frequency of channel B (168, 82, 86 kHz) is formed. For compensation of phase shifts of filters of second conversion in channel B two-pass filters are additionally inserted of six conversions in channels A and B there are used only three conversions which makes it possible to reduce noises and nonlinear products of conversion introduced into channels, to diminish sizes of transmitter and to simplify considerably generator equipment. Transmitter includes first frequency converters 1, 2, band-pass filters 3, 4, low-pass filters 5, 7, 9, second frequency converter 6, high-pass filter 8, and adder 10. EFFECT: reduced induced distortions. 1 dwg

Description

 The invention relates to communication technology, in particular to devices for transmitting stereo broadcast signals along the primary paths of multichannel communication systems.

кГц

. Очевидно, что исходные сигналы каналов А и В в принципе могут быть преобразованы в сигналы с виртуальными частотами 82 и 86 кГц соответственно с помощью одной ступени модуляции (с помощью несущих частот 82 и 86 кГц). В этом случае для каналов А и В потребуются разные каналоформирующие фильтры, фазочастотные характеристики которых будут существенно отличаться, и, как показал опыт, не удается обеспечить необходимую симметрию фазовых характеристик каналов А и В. Симметрия фазовых характеристик в передающей аппаратуре, выпускаемой разными фирмами, обеспечивается разными методами. Так, например, в передающем устройстве аппаратуры фирмы "Сименс" NSt-15 для образования каждого из двух каналов используются три ступени модуляции с одинаковыми каналоформирующими фильтрами в диапазоне частот 78-96 кГц. Такое решение зафиксировано в рекомендации J31 МККТ и в фирменном проспекте на аппаратуру МSt-15.The main task when switching a stereo signal through two monophonic channels in a multi-channel communication system is to ensure that the signals are in phase when they pass through channels A and B. Recommendation MKKTJ31 channels A and B with a bandwidth of 40 to 15000 Hz at a control frequency of 16.8 kHz should be placed in the frequency spectrum of the primary group (60-108 kHz) using virtual carrier frequencies 82 kHz (channel A) and 86 kHz (channel B). To obtain common-mode signals with the required accuracy in the frequency range of 40-15000 Hz, it is necessary that the phase-frequency characteristic of the channel A transmitting devices copy the phase-frequency characteristic of the channel B transmitting devices rotated 180 ^° relative to the frequency of 84 kHz

kHz

. Obviously, the original signals of channels A and B can in principle be converted into signals with virtual frequencies of 82 and 86 kHz, respectively, using one stage of modulation (using carrier frequencies 82 and 86 kHz). In this case, different channel-forming filters will be required for channels A and B, the phase-frequency characteristics of which will differ significantly, and, as experience has shown, it is not possible to provide the necessary symmetry of the phase characteristics of channels A and B. The symmetry of the phase characteristics in transmitting equipment manufactured by different companies is ensured different methods. So, for example, in the Siemens NSt-15 transmitter, for the formation of each of the two channels, three modulation steps with the same channel-forming filters in the frequency range 78-96 kHz are used. Such a decision is recorded in the J31 recommendation of the MKKT and in the corporate brochure on the MSt-15 equipment.

 The aim of the invention is to reduce the introduced distortion by reducing the stages of conversion.

 The drawing shows a structural diagram of the proposed device.

 It contains the first frequency converters 1, 2, band pass filters PF-65-82 3, 4, low-pass filter 5 low-pass filter-82, the second frequency converter 6, low-pass filter 7 low-pass filter-108, high-pass filter 8 high-pass filter-86, filter 9 low frequencies low-pass filter-108, adder 10.

 In this device, the frequency converters of channels A and B are connected in series with their bandpass filters 3 and 4, respectively, the output of the bandpass filter 3 of channel A (the output of the first conversion stage) is connected through series-connected filters LPF-82 5 and LPF-108 7 with the first input of the adder and the output of the band-pass filter 4 of channel B is connected to the second input of the summing device through a second converter 6 connected in series, HPF-86 filters 8 and HPF-108 9 filters.

 The device operates as follows.

 The original signals of channels A and B in the frequency spectrum of 30-15000 Hz are fed to the inputs of the first converters 1 and 2, where signals are generated using the carrier frequency 82 kHz in the frequency spectrum 67-81, 970 kHz. These signals passing through bandpass filters 3 and 4, which clean the signals from spurious conversion products. From the output of the filter 4, the signal of channel B goes to the second converter 6, where a signal of 86.030-101 kHz is generated using a carrier frequency of 168 kHz. This frequency spectrum corresponds to the linear frequency spectrum of channel B. At the output of the converter 6, filters HPF-86 and LPF-108 are installed. The HPF-86 filter 8 protects the linear path from the direct passage of the 67-82 kHz signal through the converter 6, and the HPF-108 9 filter is necessary to eliminate the upper side frequency band and the remainder of the frequency of -168 kHz at the output of the converter 6. From the output of the low-pass filter-108 9, the linear signal of channel B goes to the adder 10 and then to the line. The signal of channel A after the first conversion and passage through filter 3 has a linear frequency spectrum of 67-81.97 kHz. This signal from the output of filter 3 goes to filters 5 and 7. The low-pass filter 82 has a phase-frequency characteristic that is symmetric with respect to the high-pass filter, and the low-pass filter has a straight-line phase-frequency response in the spectrum of 60-108 kHz. Thus, filters 5 and 7 introduced into channel A compensate for phase-frequency shifts introduced into channel B by filters 8 and 9. From the output of filter 7, the signal of channel A goes to the first input of the adder and then to the line.

 The transmitting device of the MSt-15 equipment, which is a prototype, was selected as the base object. In relation to this device, the proposed device is simpler, since the filters introduced into channel A made it possible to dispense with one conversion in channel A (instead of three) and two conversions in the second channel (instead of three), which reduced the noise and nonlinear conversion products introduced into the channels.

Claims (1)

 STEREOPHONIC BROADCASTING TRANSMISSION SYSTEM IN A MULTI-CHANNEL PHONE TRANSMISSION SYSTEM, containing in the first channel a first frequency converter and a band-pass filter, as well as a low-pass filter, the output of which is connected to the first input of the adder, and in the second channel a series-connected first frequency converter, a band-pass filter and a second frequency converter, as well as a low-pass filter, the output of which is connected to the second input of the adder, characterized in that, in order to reduce To introduce distortion by reducing the conversion steps, a low-pass filter is introduced into the first channel, the input of which is connected to the output of the bandpass filter, and the output is connected to the low-pass filter input, and a high-pass filter is introduced into the second channel, the input of which is connected to the output of the second frequency converter , and the output is with the input of the low-pass filter.